CN108473284B - Passenger conveyors - Google Patents

Abstract

A kind of passenger conveyors are obtained, original position can automatically restored to relative to floor after the earthquake on a large scale.Include quasi- fixed mechanism, it is in the case where acting on the size close to power between truss and a floor less than preset specified value towards the direction for making truss close to a floor, constrain movement of the truss to the direction close to a floor, close to power size be specified value more than in the case where, release to movement from truss to the direction close to a floor constraint；And truss resetting-mechanism, truss is released to the constraint of the movement in the direction close to a floor, towards making truss far from the direction of a floor in the case where leaving power and act between truss and a floor, before truss moves along its length relative to another floor, truss resetting-mechanism moves truss along its length relative to a floor, and the size between truss and a floor is made to become preset predetermined size.

Description

Passenger conveyors

Technical field

The present invention relates to truss to be supported on the passenger conveyors of building by support member.

Background technique

The truss of escalator across in short transverse and horizontal direction mutually from floor between and be arranged.In truss Both ends be equipped with the support member of angle steel, the one end of truss or both ends with can on the length direction of truss relative to The transitory state of floor sliding is supported on floor.In such escalator, in the branch that the on-fixed side of truss is arranged Support part part makes a relative move relative to the supporting plate in storey setting, thus for example prevents in the case where earthquake occurs Biggish stress is generated between truss and supporting plate.Therefore, when the direction that building broadens by earthquake to floor gap size is shaken In the case where dynamic, by substantially ensuring the length i.e. amount of lap of the part contacted in support member with supporting plate, truss can be prevented It falls from floor.Also, in the case that the direction that building narrows by earthquake to floor gap size is shaken, by sufficiently really The gap between truss and floor is protected, can prevent truss from being compressed in length direction.

Support member is the component for supporting the full payload of escalator, thus the gap between truss and floor is biggish In the case of, the load for acting on support member increases.Therefore, for only the one end of the length direction of truss ensure truss and The fixed truss in the one end in the gap between floor, it is difficult to which setting copes with floor gap size when extensive earthquake occurs The sufficient clearance of variation.The both ends of length direction in truss are ensured with the both ends in the gap between truss and floor are non-solid Fixed truss, when can cope with earthquake generation by the aggregate value in the gap between the length direction both ends and each floor of truss Floor gap size variation, it is thus possible to cope with extensive earthquake occur when floor gap size variation.But truss Length direction both ends are not secured to each floor, even thus when small-scale earthquake occurs, escalator also can be relative to Floor misplaces.

Therefore, it has been known that there is such escalators in the past, by the rotational support body for being erected in supporting plate and are fixed in The support member of truss engages, and when extensive earthquake occurs, thus the variation of floor gap size is coped in the fracture of rotational support body (for example, referring to patent document 1).

Existing technical literature

Patent document

Patent document 1: Japanese Unexamined Patent Publication 2015-78021 bulletin

Summary of the invention

Problems to be solved by the invention

Although however, can prevent from misplacing when small-scale earthquake occurs, and can be answered when extensive earthquake occurs Variation to floor gap size, but after extensive earthquake, the fracture of rotational support body occurs, escalator can be relative to floor It misplaces.As a result, there are the following problems, i.e., in recovery after the earthquake on a large scale, it is necessary to be sling with crane etc. Escalator makes it be restored to original position.

The present invention provides a kind of passenger conveyors, after the earthquake, can automatically restore on a large scale relative to floor Position originally.

The means used to solve the problem

Passenger conveyors of the invention are supported by a support member of the length direction one end setting in truss In a floor of building, it is supported on and is built by another support member being arranged in length direction the other end of truss Another floor of object is built, passenger conveyors include quasi- fixed mechanism, make truss close to the direction of a floor in direction In the case where being less than preset specified value for the size close to power between truss and a floor, constraint truss is to connecing The movement in the direction of a nearly floor is released to truss in the case where the size close to power is specified value or more to close to one The constraint of the movement in the direction of a floor；And truss resetting-mechanism, in the movement to truss to the direction close to a floor Constraint be released from, towards the feelings leaving power and acting between truss and a floor far from the direction of a floor that make truss Under condition, before truss moves along its length relative to another floor, truss resetting-mechanism makes truss relative to a building Layer moves along its length, and the size between truss and a floor is made to become preset predetermined size.

Invention effect

Passenger conveyors according to the present invention, have truss resetting-mechanism, to truss to the direction close to a floor Movement constraint be released from, size between truss and a floor is less than predetermined size, towards making truss far from a building The power in the direction of layer is left in the case that power acts between truss and a floor, in truss relative to another floor edge Before length direction is mobile, which move truss along its length relative to a floor, makes truss and one Size between a floor becomes predetermined size, thus after the earthquake, can automatically restore on a large scale relative to floor Position originally.

Detailed description of the invention

Fig. 1 is the side view for showing the major part of escalator of embodiments of the present invention 1.

Fig. 2 is the enlarged drawing for showing the upper layer side section of the escalator of Fig. 1.

Fig. 3 is the top view for showing the upper layer side section of the escalator of Fig. 2.

Fig. 4 is the enlarged drawing of the support member for showing Fig. 2, quasi- fixed pin and supporting plate.

Fig. 5 is the enlarged drawing for showing lower layer's side section of the escalator of Fig. 1.

Fig. 6 is the skeleton diagram for being shown provided with the building of escalator of Fig. 1.

Fig. 7 be show in the building of Fig. 6 earthquake occur when building inclination, upper layer side floor and truss it Between gap and lower layer side floor and truss between this three of gap relationship figure.

Fig. 8 is to show previous escalator in the figure of state on a large scale after the earthquake.

Fig. 9 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 2.

Figure 10 is the top view for showing the variation of upper layer side section of escalator shown in Fig. 9.

Figure 11 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 3.

Figure 12 be along Figure 11 XII-XII line to pseudosection.

Figure 13 be along Figure 11 XIII-XIII line to pseudosection.

Figure 14 is inclination, upper layer side floor and the truss for showing the building when earthquake occurs in the building of Fig. 6 Between gap and lower layer side floor and truss between this three of gap relationship figure.

Figure 15 is the side view for showing the upper layer side section of the escalator of embodiments of the present invention 4.

Figure 16 be along Figure 15 XVI-XVI line to pseudosection.

Figure 17 is the top view for showing the upper layer side section of the escalator of Figure 15.

Figure 18 is the side view for showing the upper layer side section of the escalator of embodiments of the present invention 5.

Figure 19 is the figure for showing the balance of the power in friction portion of Figure 18.

Figure 20 is the calculated result of the relationship of the friction coefficient μ and tiltangleθ when showing the self weight mg for setting truss as 100kN Table.

Figure 21 is to show the friction portion of Figure 19 departing from the side view of the state of pit.

Figure 22 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 6.

Figure 23 be along Figure 22 XXIII-XXIII line to pseudosection.

Figure 24 be along Figure 22 XXIV-XXIV line to pseudosection.

Specific embodiment

Embodiment 1

Fig. 1 is the side view for showing the major part of escalator of embodiments of the present invention 1.In this embodiment, as Passenger conveyors are illustrated escalator.Escalator crosses over the upper layer as a floor in building in the figure Side floor 1a and as another floor in building lower layer side floor 1b and be arranged.Truss 2 is made of the beam of steel.? The length direction both ends of truss 2 are equipped with a pair of of the support member 3 being made of angle steel.In this embodiment, by the length direction of truss 2 It part in both ends by the side upper layer side floor 1a, will be in the length direction both ends of truss 2 as length direction one end 2a Part by the side lower layer side floor 1b is as length direction the other end 2b.Also, length will be fixed in a pair of of support member 3 The support member 3 for spending direction one end 2a is a support member as support member 3a, will be fixed in a pair of of support member 3 In length direction the other end 2b support member 3 be another support member as support member 3b.Therefore, escalator is logical It crosses and is supported on upper layer side floor 1a in the support member 3a of length direction one end 2a setting, by the length direction other end The support member 3b of portion 2b setting is supported on lower layer side floor 1b.In this embodiment, length direction refers to truss 2 viewed from above When truss 2 length direction, i.e. direction shown in the arrow X of Fig. 1.Also, in this embodiment, short transverse refers to from side to sight The short transverse of truss 2 when examining truss 2, i.e. direction shown in the arrow Y of Fig. 1.

Escalator has such quasi- fixed mechanism: making truss 2 close to the power in the direction of upper layer side floor 1a in direction In the case where acting between truss 2 and upper layer side floor 1a close to power, it is less than preset rule in the size close to power In the case where definite value, the movement of quasi- fixed mechanism constraint truss 2 to the direction close to upper layer side floor 1a, by truss 2 and upper Size between layer side floor 1a maintains preset predetermined size, in the situation that the size close to power is specified value or more Under, the quasi- fixed mechanism release to movement from truss 2 to the direction close to upper layer side floor 1a constraint.

Also, escalator have such truss resetting-mechanism: to truss 2 to the direction close to upper layer side floor 1a The constraint of movement be released from, in the case that size between truss 2 and upper layer side floor 1a is less than predetermined size, towards making The power in direction of the truss 2 far from upper layer side floor 1a is left in the case that power acts between truss 2 and upper layer side floor 1a, Before truss 2 moves along its length relative to lower layer side floor 1b, which makes truss 2 relative to upper layer side Floor 1a is moved along its length, and the size between truss 2 and upper layer side floor 1a is made to become predetermined size.

Fig. 2 is the enlarged drawing for showing the upper layer side section of the escalator of Fig. 1, Fig. 3 be show Fig. 2 escalator it is upper The top view of layer side section.Support member 3a includes vertical piece 31, be fixed in length direction one end 2a towards length On face on the outside of direction, and extend along short transverse；And lateral piece 32, from the top of vertical piece 31 towards the length of truss 2 It spends on the outside of direction and extends.Vertical piece 31 is configured to opposed with upper layer side floor 1a on the length direction of truss 2.

In the lateral piece 32 of support member 3a, quasi- fixed pin is formed in a manner of running through lateral piece 32 in the height direction With hole 321.Also, in the lateral piece of support member 3a 32, length is formed in a manner of running through lateral piece 32 in the height direction Hole 322.Long hole 322 is configured to extend when viewed from above along the length direction of truss 2.Long hole 322 is used than quasi- fixed pin Hole 321 configures on the outside of the length direction of truss 2.Quasi- fixed pin hole 321 and long hole 322 are configured to the length in truss 2 It spends adjacent on direction.In other words, quasi- fixed pin is configured in identical position with hole 321 and long hole 322 in the direction of the width.? In the example, the width direction of the truss 2 when width direction refers to truss 2 viewed from above, i.e. direction shown in the arrow Z of Fig. 3.

Quasi- fixed mechanism includes quasi- fixed pin 41, is inserted into quasi- fixed pin in hole 321, and constraint truss 2 is to upper layer side building The movement of layer 1a；And supporting plate 42, upper layer side floor is fixed at than the quasi- fixed pin position on the lower of hole 321 1a, and it is formed with the inclined surface 421 being inclined relative to horizontal.

The lower end of quasi- fixed pin 41 is contacted with inclined surface 421, and thus quasi- fixed pin 41 is supported on supporting plate 42.Standard is solid Rationed marketing 41 is formed as cylindrical shape.Radial undersized of the radial size of quasi- fixed pin 41 than quasi- fixed pin hole 321. Therefore, quasi- fixed pin 41 can be moved relative to supporting plate 42 along short transverse in the state of being inserted into quasi- fixed pin hole 321 It is dynamic.

Supporting plate 42 is fixed in the upper surface of upper layer side floor 1a.Truss 2 is leaned in the configuration of inclined surface 421 in supporting plate 42 The end of side.Inclined surface 421 is with upward and far from being inclined relative to horizontal in a manner of truss.

Truss resetting-mechanism includes pair of sliding component 51, is set to the lateral piece 32 of supporting plate 42 and support member 3a Between；And anchor pin 52, it is fixed in upper layer side floor 1a, and be inserted into long hole 322.

Pair of sliding component 51 discretely configures in the direction of the width.Slide unit 51 is prolonged with the length direction along truss 2 The mode stretched configures.Slide unit 51 is fixed in the upper surface of supporting plate 42.The lateral piece 32 of support member 3a is placed in The upper surface of slide unit 51.Support member 3a being capable of upper surface on the length direction of truss 2 relative to slide unit 51 It is slided.

Anchor pin 52 is formed as cylindrical shape.Size of the radial size of anchor pin 52 than the width direction of long hole 322 It is smaller.Therefore, anchor pin 52 can move along its length the length side of long hole 322 in the state of being inserted into long hole 322 To size.Slide unit 51 is run through in the lower end of anchor pin 52, and is driven into supporting plate 42 from top.Anchor pin 52 is fixed In supporting plate 42, thus anchor pin 52 is fixed in upper layer side floor 1a.

A pair of of width direction fixture 6 is fixed in supporting plate 42.A pair of of width direction fixture 6 is configured in support member 3a Width direction on the outside of.A pair of of width direction fixture 6 constrains movement of the support member 3a to width direction.That is, a pair of of width side To fixture 6 along the length direction guiding support part 3a of truss 2.The shifting of length direction one end 2a in the direction of the width as a result, It moves restrained.

The vertical piece of size L1 between the vertical piece 31 and upper layer side floor 1a of support member 3a and support member 3b and Size between lower layer side floor 1b add up it is sufficiently large, even in the case where extensive earthquake occurs, support member 3a's Vertical piece 31 and upper layer side floor 1a are not also contacted.Even if the part in the inner wall of anchor pin 52 and long hole 322 by 2 side of truss connects Touching, also can to truss 2 generate compressing force, thus make long hole 322 length direction size L2 be greater than anchor pin 52 diameter d1 The aggregate value of the size L1 of length direction between the vertical piece 31 and upper layer side floor 1a of support member 3a, avoids anchor pin 52 and long hole 322 inner wall in by 2 side of truss part contact.By in the inner wall of anchor pin 52 and long hole 322 farthest away from truss 2 Part contact when, the size between truss 2 and upper layer side floor 1a be set as predetermined size.In truss 2 and upper layer side floor In the case that size between 1a is predetermined size, quasi- fixed pin hole 321 is configured in the upper of the inclined surface 421 of supporting plate 42 Side.

Anchor pin 52 is designed to such intensity, that is, even if truss 2 moves along its length relative to lower layer side floor 1b The inertia force of truss 2 when the frictional force generated when dynamic and earthquake occur acts on anchor pin 52, and anchor pin 52 is also not broken.It rubs Wiping power is calculated according to the weight and supporting plate 42 of escalator or the coefficient of friction of slide unit 51, and inertia force is basis The weight of escalator and territory Ministry of Communications announce No. 1046 as defined in level standard magnitude calculation.

Fig. 4 is the enlarged drawing of the support member 3a for showing Fig. 2, quasi- fixed pin 41 and supporting plate 42.In quasi- 41 shape of fixed pin At there is multiple notch 411.Multiple notch 411 are arranged along short transverse.In the height direction between adjacent notch 411 Support the size between the part of quasi- fixed pin 41 and the lateral piece 32 of support member 3a consistent in size and supporting plate 42.It is multiple Be configured in notch 411 size between the notch 411 of bottom and the lower end of quasi- fixed pin 41 in the height direction Size between adjacent notch 411 is consistent.Therefore, notch 411 is configured to be supported on supporting plate 42 in quasi- fixed pin 41 In the case where, it is consistent with the lower surface of lateral piece 32 of support member 3a in the height direction.

The part that notch 411 is formed in quasi- fixed pin 41 is designed to such intensity, that is, though truss 2 relative to The inertia force of truss 2 when the frictional force and earthquake that lower layer side floor 1b is generated when moving along its length occur acts on the portion Point, the part is also not broken, and the portion fractures under the action of load smaller than the buckling load of truss 2.Therefore, quasi- solid Part production when effect has truss 2 to move along its length relative to lower layer side floor 1b of notch 411 is formed in rationed marketing 41 It is not broken in the case where the inertia force of truss 2 when raw frictional force and earthquake occur, and it is small in the buckling load than truss 2 It is broken under the action of power.

In other words, specified value is set to such value in advance, the value is than truss 2 relative to upper layer side floor 1a along length The inertia force of truss 2 when the frictional force and earthquake that direction generates when mobile occur is big, smaller than the buckling load of truss 2.Therefore, Truss 2 is acted on close to power between truss 2 and upper layer side floor 1a close to the power in the direction of upper layer side floor 1a in direction In the case where, in the case where the size close to power is less than specified value, quasi- fixed pin 41 is not broken, to constrain truss 2 to connecing The movement in the direction of nearly upper layer side floor 1a, maintains preset rule for the size between truss 2 and upper layer side floor 1a Scale cun.On the other hand, in the case where the size close to power is specified value or more, support member 3a in quasi- fixed pin 41 and Portion fractures between supporting plate 42, thus quasi- fixed pin 41 releases the shifting to truss 2 to the direction close to upper layer side floor 1a Dynamic constraint.

Fig. 5 is the enlarged drawing for showing lower layer's side section of the escalator of Fig. 1.Supporting plate 43 is fixed in lower layer side floor The upper surface of 1b.Support member 3b includes vertical piece 33 as support member 3a, is fixed in length direction the other end 2b's extends towards on the face on the outside of length direction, and along short transverse；And lateral piece 34, from the top court of vertical piece 33 Extend on the outside of to the length direction of truss 2.Vertical piece 33 is configured on the length direction of truss 2 and 1b pairs of lower layer side floor It sets.Support member 3b can the upper surface on the length direction of truss 2 relative to supporting plate 43 slided.Support member 3a Lateral piece 32 and slide unit 51 between frictional force less than support member 3b lateral piece 34 and supporting plate 43 between rubbing Wipe power.

It is fixed with a pair of of width direction fixture in supporting plate 43, but is not illustrated.A pair of of width direction fixture is configured in On the outside of the width direction of support member 3b.A pair of of width direction fixture constrains movement of the support member 3b to width direction.That is, one To width direction fixture along the length direction guiding support part 3b of truss 2.Length direction the other end 2b is in width side as a result, Upward movement is restrained.

In the following, the movement of escalator when earthquake occurs is illustrated.Fig. 6 is to be shown provided with helping automatically for Fig. 1 The skeleton diagram of the building of ladder.In this embodiment, escalator is arranged across 2 layers and 3 layers built in the building to have three layers.And And in this embodiment, as the direction of building inclination, it will be set as positive to the inclined direction in the right side of Fig. 6, it will be to a left side of Fig. 6 The inclined direction in side is set as negative sense.

Fig. 7 is inclination, upper layer side floor 1a and the truss for showing the building when earthquake occurs in the building of Fig. 6 The figure of the relationship of this three of gap between gap and lower layer side floor 1b and truss 2 between 2.It, will be automatic in Fig. 7 The upper layer side section of staircase shows lower layer's side section of escalator as on-fixed side as quasi- affixed side.

(1) of Fig. 7 shows the state for being provided with escalator.In this case, be configured to will be quasi- for quasi- affixed side Fixed pin 41 is inserted into the state in quasi- fixed pin hole 321.Ruler between upper layer side floor 1a and the vertical piece 33 of support member 3a Size between very little and lower layer side floor 1b and the vertical piece 33 of support member 3b is respectively the size determined according to regulation. At this point, the size between truss 2 and upper layer side floor 1a is preset predetermined size, anchor pin 52 is interior with long hole 322 It is contacted in wall farthest away from the part of truss 2.

(2) of Fig. 7, which are shown, occurs middle and small scale earthquake, building inclined state towards the positive direction.So-called middle and small scale Shake refers to the earthquake generated according to building standard method operational command the 82nd article 2 calculated stratified deformation angle displacements below.By It is tilted towards the positive direction in building, the upper layer side section in escalator moves towards the positive direction.Upper layer side building in escalator as a result, Size between layer 1a and lower layer side floor 1b increases.In this case, in on-fixed side, support member 3b is relative to support Plate 43 slides, and thus truss 2 moves along its length relative to lower layer side floor 1b, the vertical piece 33 of support member 3b and lower layer Gap between the floor 1b of side increases compared with situation (1).When being moved along its length with truss 2 relative to lower layer side floor 1b The comparable load of inertia force of truss 2 when the frictional force of generation and earthquake occur acts on anchor pin 52.

(3) of Fig. 7, which are shown, occurs middle and small scale earthquake, building towards negatively inclined state.Since building is towards negative To inclination, the upper layer side section in escalator is mobile towards negative sense.Upper layer side floor 1a and lower layer side in escalator as a result, Size between floor 1b reduces.In this case, in on-fixed side, support member 3b is slided relative to supporting plate 43, by This truss 2 moves along its length relative to lower layer side floor 1b, the vertical piece 33 and lower layer side floor 1b of support member 3b it Between gap reduce compared with situation (1).Although between the upper layer side floor 1a in escalator and lower layer side floor 1b The shaking for the compression direction that size reduces, but due to also having between the vertical piece 33 of support member 3b and lower layer side floor 1b There is gap, the frictional force and earthquake generated when consequently only that moving along its length with truss 2 relative to lower layer side floor 1b The comparable load of inertia force of truss 2 when generation acts on quasi- fixed pin 41.

(4) of Fig. 7, which are shown, occurs extensive earthquake, building inclined state towards the positive direction.So-called extensive earthquake is Refer to the displacement at 5 times of stratified deformation angle when generating according to the 82nd article of 2 calculated middle scale earthquake of building standard method operational command Earthquake.Since building tilts towards the positive direction, the upper layer side section in escalator moves towards the positive direction.Also, in such case Under, the size between upper layer side floor 1a and lower layer side floor 1b increases compared with situation (2).As a result, in on-fixed side, support Component 3b is slided relative to supporting plate 43, and thus truss 2 moves along its length relative to lower layer side floor 1b, support member 3b Vertical piece 33 and lower layer side floor 1b between gap increase compared with situation (2).The supporting plate 43 of support member 3b with Biggish amount of lap is equipped between lower layer side floor 1b, even so that extensive earthquake, building occurs is inclined towards the positive direction In the case of, support member 3b will not fall from lower layer side floor 1b.

(5) of Fig. 7, which are shown, occurs extensive earthquake, building towards negatively inclined state.Since building is towards negative sense It tilts, the upper layer side section in escalator is mobile towards negative sense.Also, in this case, upper layer side floor 1a and lower layer side Size between floor 1b reduces compared with situation (3).As a result, in on-fixed side, support member 3b is sliding relative to supporting plate 43 Dynamic, thus truss 2 moves along its length relative to lower layer side floor 1b, the lateral piece 34 and lower layer side floor of support member 3b Gap between 1b disappears.As a result, truss 2 is compressed in the longitudinal direction, size and the compressive load for acting on truss 2 Identical load acts on quasi- fixed pin 41.

(6) of Fig. 7 show the state for reaching specified value or more close to the size of power.Specified value is such value, the value The purlin when frictional force generated when moving along its length than support member 3b relative to lower layer side floor 1b and earthquake occur The inertia force of frame 2 is big, smaller than the buckling load of truss 2.The size substantially tilted to towards negative sense close to power in building reaches rule When more than definite value degree, the compressive load for acting on truss 2 increases, the load for acting on truss 2 reach buckling load it Before, quasi- fixed pin 41 is broken.Since quasi- fixed pin 41 is broken, support member 3a is moved along its length relative to upper layer side floor 1a Dynamic, the gap between the vertical piece 31 and upper layer side floor 1a of support member 3a reduces compared with situation (5).Support portion as a result, Size between part 3a and support member 3b correspond to the variation of the size between upper layer side floor 1a and lower layer side floor 1b and Variation, the compressive load for acting on truss 2 disappear.Fracture quasi- fixed pin 41 fragment along supporting plate 42 inclined surface 421 It falls, the remaining part of quasi- fixed pin 41 is moved together with support member 3a relative to upper layer side floor 1a along its length. As a result, the size between truss 2 and upper layer side floor 1a is less than predetermined size.

In the case that (7) of Fig. 7 show the size between truss 2 and upper layer side floor 1a less than predetermined size, from Opening force acts on the state between truss 2 and upper layer side floor 1a.In the vertical piece 33 and lower layer side floor from support member 3b The state that size between 1b between very close to each other and truss 2 and upper layer side floor 1a is less than predetermined size rises, and building is opened When beginning to shake towards negative sense, the size between upper layer side floor 1a and lower layer side floor 1b starts to increase.Support member 3a as a result, The friction between lateral piece 34 and supporting plate 43 of the frictional force less than support member 3b between lateral piece 32 and slide unit 51 Power, thus before support member 3b is moved along its length relative to lower layer side floor 1b, support member 3a is relative to upper layer Side floor 1a is moved along its length, is up to contacting in anchor pin 52 and the inner wall of long hole 322 farthest away from the part of truss 2 Only.When size between truss 2 and upper layer side floor 1a reaches predetermined size, in the inner wall of anchor pin 52 and long hole 322 most Part far from truss 2 contacts, and quasi- fixed pin 41 moves downwards by self weight and is supported on inclined surface 421.Support member The vertical piece 33 and lower layer side floor 1b of 3b becomes the state to contact with each other, until in the inner wall of anchor pin 52 and long hole 322 Until the contact of the part of truss 2.

(8) of Fig. 7, which are shown, moves downwards after being supported on inclined surface 421 in quasi- fixed pin 41 by self weight, builds Build the state that the inclination of object disappears.Since building reverts to original setting state, upper layer side floor 1a and lower layer side floor Size between 1b increases compared with situation (7).As a result, farthest away from the part of truss 2 in the inner wall of anchor pin 52 and long hole 322 Contact, anchor pin 52 pull support member 3a along its length.At this point, in on-fixed side, 34 phase of lateral piece of support member 3b Lower layer side floor 1b is moved along its length, the size between the vertical piece 33 and lower layer side floor 1b of support member 3b with Situation (1) is identical.

As described above, middle and small scale earthquake is occurring for escalator according to embodiment 1 of the present invention In the case of, truss 2 carries out the fixed movement in one end, thus the dislocation between truss 2 and upper layer side floor 1a can be eliminated.And And the escalator, in the case where extensive earthquake occurs, truss 2 carries out the revocable movement in both ends, it is thus possible to corresponding The variation of size between upper layer side floor 1a and lower layer side floor 1b, makes the ruler between support member 3a and support member 3b Very little variation prevents compressive load from acting on truss 2.Also, the escalator after extensive earthquake occurs building restore In the case where original state, anchor pin 52 is contacted with the inner wall of long hole 322 farthest away from the part of truss 2, anchor pin 52 Move support member 3a along its length, it is thus possible to make between the vertical piece 33 of support member 3b and lower layer side floor 1b Size reverts to original state automatically.Also, size of the escalator between truss 2 and upper layer side floor 1a is less than rule In the case where scale cun, the frictional force that truss 2 generates when moving along its length relative to upper layer side floor 1a is less than 2 phase of truss The frictional force generated when being moved along its length for lower layer side floor 1b, it is thus possible to first make truss 2 relative to upper layer side building Layer 1a is moved along its length, so that the size between truss 2 and upper layer side floor 1a is become predetermined size, is then made 2 phase of truss Lower layer side floor 1b is moved along its length, the size between truss 2 and lower layer side floor 1b is made to become original size.

Also, the escalator extensive earthquake occurs, act between truss 2 and upper layer side floor 1a close to power In the case where more than specified value, quasi- fixed pin 41 is broken, and a part of the quasi- fixed pin 41 of fracture is fallen, in truss 2 and upper In the case that size between layer side floor 1a becomes predetermined size, quasi- fixed pin 41 is supported on inclined surface 421 by self weight, Movement of the truss 2 to the direction close to upper layer side floor 1a can be thus constrained again.Also, after extensive earthquake occurs, It does not need to extract the quasi- fixed pin 41 to be fractureed by operating personnel and new quasi- fixed pin 41 is installed, it is thus possible to for repeatedly big The generation of scale earthquake and tell on.

Also, support member 3a is only by forming quasi- fixed pin hole 321 and long hole 322 in previous support member Production, it is thus possible to easily make support member 3a.

Fig. 8 is to show previous escalator in the figure of state on a large scale after the earthquake.Previous escalator exists In the case where extensive earthquake occurs, the position of truss 2 will deviate from installation site, such as in the presence of truss 2 shown in (a) such as Fig. 8 The case where being located proximate to the lower layer side floor side 1b or the truss 2 as shown in (b) of Fig. 8 is located proximate to the side upper layer side floor 1a The case where.In these cases, even if truss 2 does not receive compressive load and do not buckle, it is also desirable to use crane to restore Etc. the operation sling truss 2 it is made to revert to origin-location.In the present invention, the position of the truss 2 after earthquake utilizes building Shaking and revert to original position i.e. installation site automatically, because of the operation without truss 2 to be reverted to origin-location.

In addition, illustrating such structure in the embodiment 1: a floor is set as upper layer side floor 1a, it will be another A floor is set as lower layer side floor 1b, and a support member is set as support member 3a, another support member is set as supporting Component 3b but it is also possible to be a floor is set as lower layer side floor 1b, another floor is set as to upper layer side floor 1a, by one A support member is set as support member 3b, another support member is set as to the structure of support member 3a.That is, can also will be automatic Lower layer's side section of staircase is as quasi- affixed side, using the upper layer side section of escalator as on-fixed side.

In addition, illustrating that slide unit 51 is arranged between support member 3a and supporting plate 42 in above embodiment 1 Structure, however, you can also not which slide unit 51 is arranged between support member 3a and supporting plate 42, and support member 3b and holding Friction member is set between supporting plate 43.In this case, to truss 2 towards the movement in the direction close to upper layer side floor 1a Constraint be released from, size between truss 2 and upper layer side floor 1a is less than predetermined size, leaves power act on truss 2 and on In the case where between layer side floor 1a, when friction member moves support member 3b along its length relative to lower layer side floor 1b The frictional force of generation is greater than the frictional force generated when support member 3a is moved along its length relative to upper layer side floor 1a.

In addition, illustrating that the shape of quasi- fixed pin 41 and anchor pin 52 is the knot of cylindrical shape in above embodiment 1 Structure, but quasi- fixed pin 41 and the shape of anchor pin 52 are not limited to cylindrical shape, are also possible to other shapes.

In addition, being constituted by forming notch 411 in quasi- fixed pin 41 in following load in above embodiment 1 The lower structure being broken of effect, what which generated when moving along its length relative to lower layer side floor 1b rubs The inertia force for wiping the truss 2 when power and earthquake generation is big, smaller than the buckling load of truss 2, but as long as quasi- fixed pin 41 itself Meet the condition, is then also possible to not form the quasi- fixed pin 41 of notch 411.

Embodiment 2

Fig. 9 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 2.Quasi- fixed pin 41 and The respective number of anchor pin 52 is two.One alignment fixed pin 41 discretely configures in the direction of the width.A pair of of anchor pin 52 exists It is discretely configured in width direction.In support member 3a, be accordingly respectively formed with quasi- fixed pin 41 and anchor pin 52 there are two Quasi- fixed pin hole 321 and two long holes 322.

It is designed to that quasi- fixed pin 41 is than truss 2 by forming notch 411 in quasi- fixed pin 41 in the embodiment 1 It is broken under the action of the small load of buckling load, and is designed in embodiment 2, make total intensity of two quasi- fixed pins 41 Reach the intensity that two quasi- fixed pins 41 are broken under the action of the load smaller than the buckling load of truss 2.

Also, anchor pin 52 in the embodiment 1, is designed to such intensity, that is, even if truss 2 is relative to lower layer The inertia force of truss 2 when the frictional force and earthquake that side floor 1b is generated when moving along its length occur acts on anchor pin 52, anchor pin 52 is also not broken, and in embodiment 2, by total Intensity Design of two anchor pins 52 at such intensity, That is, even if truss 2 when frictional force that truss 2 generates when moving along its length relative to lower layer side floor 1b and earthquake occur Inertia force act on two anchor pins 52, the two anchor pins 52 are also not broken.Therefore, the anchor pin 52 of embodiment 2 Thickness is less than the thickness of the anchor pin 52 of embodiment 1.Other structures are identical as embodiment 1.

Production when buckling load, the truss 2 of truss 2 when earthquake occurs move along its length relative to lower layer side floor 1b The inertia force of truss 2 when raw frictional force and earthquake occur, high, truss 2 the weight equal-specification according to the layer of truss 2 and Difference, thus the intensity that alignment and fixation pin 41 and anchor pin 52 require is different according to set object.Therefore, it is necessary to various The quasi- fixed pin 41 of thickness and anchor pin 52, and in embodiment 2, quasi- fixed pin 41 and anchor pin 52 are respectively provided with each two It is a, it is thus possible to the intensity for adjusting alignment and fixation pin 41 and the requirement of anchor pin 52, without changing quasi- fixed pin 41 and anchor pin 52 thickness.

As described above, escalator according to embodiment 2 of the present invention, quasi- fixed pin 41 and anchor pin 52 It is respectively provided with two, it is thus possible to the intensity for adjusting alignment and fixation pin 41 and the requirement of anchor pin 52, it is quasi- fixed without changing Pin 41 and the thickness of anchor pin 52.

In addition, illustrate that quasi- fixed pin 41 and anchor pin 52 are respectively provided with two structures in above embodiment 2, But quasi- fixed pin 41 and anchor pin 52 can be any number respectively.Also, quasi- fixed pin 41 and the respective number of anchor pin 52 It may not be identical quantity.Figure 10 is the top view for showing the variation of upper layer side section of escalator shown in Fig. 9.? In Figure 10, it is equipped with a quasi- fixed pin 41, if there are two anchor pins 52.In this case, it can also obtain and embodiment 2 The identical effect of structure.Quasi- fixed pin 41, anchor pin 52, the quantity of slide unit 51 and configuration can carry out various combinations and come It uses.

In addition, quasi- fixed pin hole 321 and long hole 322 are adjacent to configuration in the longitudinal direction in embodiment 2, but Can also be as shown in Figure 10, quasi- fixed pin hole 321 and long hole 322 are discretely configured in the direction of the width.In such case Under, when observing in the width direction, quasi- fixed pin hole 321 and long hole 322 are overlappingly configured.It is used as a result, with quasi- fixed pin The case where hole 321 is adjacent to configuration with long hole 322 in the longitudinal direction is compared, and does not need that quasi- fixed pin hole 321 and length is arranged The interval about length direction between hole 322, can reduce the size of the length direction of support member 3a.

Embodiment 3

Figure 11 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 3, Figure 12 be along The XII-XII line of Figure 11 to pseudosection, Figure 13 be along Figure 11 XIII-XIII line to pseudosection.In support portion The lateral piece 32 of part 3a has been formed extended at both sides quasi- fixed pin from the end face on the outside of the length direction of lateral piece 32 towards vertical piece 31 With hole 323.Quasi- fixed pin hole 323 is formed as in the height direction through lateral piece 32.The length side in quasi- fixed pin hole 323 End outward reaches the end face on the outside of the length direction of lateral piece 32.That is, quasi- fixed pin is become with hole 323 from lateral piece 32 Length direction on the outside of the slot that is extended to form towards vertical piece 31 of end face.Also, in the formation of the lateral piece of support member 3a 32 There is a pair of of long hole 322.

Quasi- fixed mechanism includes quasi- fixed pin 41, is inserted into quasi- fixed pin hole 323；Cylinder barrel 44, more solid than standard Rationed marketing is fixed in upper layer side floor 1a at the position on the lower of hole 323, and the lower end of quasi- fixed pin 41 is inserted into the cylinder barrel In 44；Spring 45 is set to the bottom of the inside of cylinder barrel 44, presses quasi- fixed pin 41 upwards；And pressing plate 46, it is fixed In support member 3a, the movement of quasi- fixed pin 41 upwards is limited.

The configuration of cylinder barrel 44 is in the gap between the vertical piece 31 and upper layer side floor 1a of support member 3a.

Spring 45 configures between the bottom and quasi- fixed pin 41 of cylinder barrel 44.

The inclined surface 461 being inclined relative to horizontal is formed in pressing plate 46.Inclined surface 461 is with upward and remote Mode from truss 2 is inclined relative to horizontal.

In the case that size between truss 2 and upper layer side floor 1a is predetermined size, quasi- fixed pin is in hole 323 Near the top for being partly arranged at cylinder barrel 44 of 2 side of truss in wall.The upper end of quasi- fixed pin 41 with inclined surface 461 by contacting And it is pressed downwards by pressing plate 46.The lower end of quasi- fixed pin 41 is pressed upwards by spring 45.

Truss resetting-mechanism has a pair of of anchor pin 52.Anchor pin 52 is inserted into long hole 322.The lower end of anchor pin 52 It is driven into supporting plate 42.Quasi- fixed pin 41 and anchor pin 52 discretely configure in the direction of the width.

The size L1 of length direction between the vertical piece 31 and cylinder barrel 44 of support member 3a be and the branch in embodiment 1 The identical size of size L1 of length direction between the vertical piece 31 and upper layer side floor 1a of support part part 3a.Other structures with Embodiment 1,2 is identical.

In the following, the movement of escalator when earthquake occurs is illustrated.Figure 14 be show in the building of Fig. 6 The inclination of building, upper layer side floor 1a when earthquake occurs and the gap between truss 2 and lower layer side floor 1b and truss The figure of the relationship of this three of gap between 2.It, will be to the right side of Figure 14 as the direction of building inclination as embodiment 1 The inclined direction in side is set as positive, will be set as negative sense to the direction of the left side of Figure 14.Also, in Figure 14, it will help automatically The upper layer side section of ladder is set as quasi- affixed side, and lower layer's side section of escalator is set as on-fixed side.

(1) of Figure 14 shows the state for being provided with escalator.In this case, be configured to will be quasi- for quasi- affixed side Fixed pin 41 is inserted into quasi- fixed pin hole 323 state for leaning on the end of 2 side of truss.Anchor pin 52 is configured to be inserted into long hole Farthest away from the state of the part of truss 2 in 322.Size and lower layer between cylinder barrel 44 and the vertical piece 31 of support member 3a Size between the vertical piece 33 of side floor 1b and support member 3b is respectively the size determined according to regulation.At this point, 2 He of truss Size between upper layer side floor 1a is predetermined size, and anchor pin 52 connects with the inner wall of long hole 322 farthest away from the part of truss 2 Touching.

(2) of Figure 14, which are shown, occurs middle and small scale earthquake, building inclined state towards the positive direction.Since building is towards just To inclination, the upper layer side section in escalator moves towards the positive direction.Upper layer side section in escalator and lower layer side as a result, / size increase.In this case, in on-fixed side, support member 3b is slided relative to supporting plate 43, thus purlin Frame 2 moves along its length relative to lower layer side floor 1b, between the vertical piece 33 and lower layer side floor 1b of support member 3b Gap increases compared with situation (1).The frictional force generated when being moved along its length with truss 2 relative to lower layer side floor 1b with And the comparable load of inertia force of the truss 2 when earthquake generation acts on anchor pin 52.

(3) of Figure 14, which are shown, occurs middle and small scale earthquake, building towards negatively inclined state.Since building is towards negative To inclination, the upper layer side section in escalator is mobile towards negative sense.Upper layer side section in escalator and lower layer side as a result, / size reduce.In this case, in on-fixed side, support member 3b is slided relative to supporting plate 43, thus purlin Frame 2 moves along its length relative to lower layer side floor 1b, between the vertical piece 33 and lower layer side floor 1b of support member 3b Gap reduces compared with situation (1).Although the size between the upper layer side section in escalator and lower layer's side section reduces Compression direction shaking, but due between the vertical piece 33 of support member 3b and lower layer side floor 1b also have gap, When the frictional force generated when consequently only that moving along its length with truss 2 relative to lower layer side floor 1b and earthquake occur The comparable load of the inertia force of truss 2 acts on quasi- fixed pin 41.

(4) of Figure 14, which are shown, occurs extensive earthquake, building inclined state towards the positive direction.Towards the positive direction due to building It tilts, the upper layer side section in escalator moves towards the positive direction.Also, in this case, upper layer side floor 1a and lower layer side Size between floor 1b increases compared with situation (2).As a result, in on-fixed side, support member 3b is sliding relative to supporting plate 43 Dynamic, thus truss 2 moves along its length relative to lower layer side floor 1b, the vertical piece 33 and lower layer side floor of support member 3b Gap between 1b increases compared with situation (2).The lateral piece 34 of support member 3b between lower layer side floor 1b be equipped with compared with Big amount of lap, even so that extensive earthquake, building occurs towards the positive direction in inclined situation, support member 3b will not It falls from lower layer side floor 1b.

(5) of Figure 14, which are shown, occurs extensive earthquake, building towards negatively inclined state.Since building is towards negative sense It tilts, the upper layer side section in escalator is mobile towards negative sense.Also, in this case, upper layer side floor 1a and lower layer side Size between floor 1b reduces compared with situation (3).As a result, in on-fixed side, support member 3b is sliding relative to supporting plate 43 Dynamic, thus truss 2 moves along its length relative to lower layer side floor 1b, the vertical piece 33 and lower layer side floor of support member 3b The gap of 1b disappears.As a result, truss 2 is compressed, size load identical with the compressive load for acting on truss 2 is acted on Quasi- fixed pin 41.

(6) of Figure 14 show the state for reaching specified value or more close to the size of power.Specified value is set to such Value, the frictional force and earthquake which generates when moving along its length than support member 3b relative to lower layer side floor 1b occur When truss 2 inertia force it is big, smaller than the buckling load of truss 2.The size close to power is substantially tilted to towards negative sense in building When reaching the degree of specified value or more, the compressive load for acting on truss 2 increases, and reaches in the load for acting on truss 2 and buckles Before load, quasi- fixed pin 41 is broken.Since quasi- fixed pin 41 is broken, support member 3a is relative to upper layer side floor 1a along length Direction is mobile, and the gap between the vertical piece 31 and upper layer side floor 1a of support member 3a reduces compared with situation (5).As a result, Size between support member 3a and support member 3b corresponds to the size between upper layer side floor 1a and lower layer side floor 1b Change and change, the compressive load for acting on truss disappears.The fragment of the quasi- fixed pin 41 of fracture edge together with support member 3a Length direction is mobile to the upper layer side side floor 1a.Become quilt in the remaining part for the quasi- fixed pin 41 that the inside of cylinder barrel 44 is arranged The state that the lateral piece 32 of support member 3a is pressurized from above by.As a result, the size between truss 2 and upper layer side floor 1a is small In predetermined size.

In the case that (7) of Figure 14 show the size between truss 2 and upper layer side floor 1a less than predetermined size, from Opening force acts on the state between truss 2 and upper layer side floor 1a.In the vertical piece 33 and lower layer side floor from support member 3b The state that size between 1b between very close to each other and truss 2 and upper layer side floor 1a is less than predetermined size rises, and building is opened When beginning shakes in the opposite direction, the size between upper layer side floor 1a and lower layer side floor 1b starts to increase.Support member 3a as a result, Lateral piece 32 and slide unit 51 between frictional force less than support member 3b lateral piece 34 and supporting plate 43 between rubbing Power is wiped, thus support member 3a is moved along its length relative to upper layer side floor 1a, until anchor pin 52 and long hole 322 Until being contacted in inner wall farthest away from the part of truss 2.Size between truss 2 and upper layer side floor 1a reaches predetermined size When, anchor pin 52 is contacted with the inner wall of long hole 322 farthest away from the part of truss 2, and quasi- fixed pin hole 323 is configured in quasi- solid The top of rationed marketing 41, quasi- fixed pin 41 are jacked up upwards by the power of spring 45 and are contacted with inclined surface 461.The standard of fracture is solid The part of rationed marketing 41 keeps the state remained on supporting plate 42.Quasi- fixed pin extends to form always support member with hole 323 In the lateral piece 32 of 3a lean on the side upper layer side floor 1a end face, even thus quasi- fixed pin 41 due to extensive earthquake generation And when being broken repeatedly, the part of the quasi- fixed pin 41 of fracture is also expressed into the side upper layer side floor 1a successively.

(8) of Figure 14, which are shown, to be moved upward by the power of spring 45 in quasi- fixed pin 41 and contacts with inclined surface 461 Afterwards, the state that the inclination of building disappears.Since building reverts to original setting state, upper layer side floor 1a and lower layer side Size between floor 1b increases compared with situation (7).As a result, farthest away from truss 2 in the inner wall of anchor pin 52 and long hole 322 Part contacts, and anchor pin 52 pulls support member 3a along its length.At this point, in on-fixed side, the lateral piece of support member 3b 34 move along its length relative to lower layer side floor 1b, the ruler between the vertical piece 33 and lower layer side floor 1b of support member 3b It is very little identical as situation (1).

As described above, escalator according to embodiment 3 of the present invention, by being formed quasi- fixed pin 41 The construction for jacking up quasi- fixed pin 41 upwards between truss 2 and upper layer side floor 1a and from below is configured, is able to suppress quasi- solid Rationed marketing 41 protrudes upwards from support member 3a.It is to cope with the generation of multiple earthquake, then quasi- in the construction of embodiment 1 The size of the length direction of fixed pin 41 increases, and the sky of quasi- fixed pin 41 is needed at the position more against the top than support member 3a Between.But even though it is not illustrated, be provided with the floor etc. of passenger's walking in the top of truss 2, thus it is difficult to ensure quasi- fixation The space of pin 41.In the construction of embodiment 3, between the quasi- configuration of fixed pin 41 is between truss 2 and upper layer side floor 1a It in gap, thus is that can easily increase the size of the length direction of quasi- fixed pin 41 using not used space originally.It is other Effect it is identical as embodiment 1.

Embodiment 4

Figure 15 is the side view for showing the upper layer side section of the escalator of embodiments of the present invention 4, Figure 16 be along The XVI-XVI line of Figure 15 to pseudosection, Figure 17 is the top view for showing the upper layer side section of the escalator of Figure 15.In reality It applies and is not provided with anchor pin 52 in mode 4, quasi- fixed pin 41 plays the effect of anchor pin 52.2 side end of truss of supporting plate 42 It is more prominent to 2 side of truss than upper layer side floor 1a.Size L1 between the vertical piece 31 and supporting plate 42 of support member 3a is and reality Apply the identical ruler of size L1 of the length direction between the vertical piece 31 of the support member 3a in mode 1 and upper layer side floor 1a It is very little.In the embodiment 1, the inclined surface 421 of supporting plate 42 is formed as with upward and far from truss 2.On the other hand, exist In embodiment 4, it is formed with and prolongs in the width direction to 2 side of truss part outstanding than upper layer side floor 1a in supporting plate 42 The long hole 423 stretched, the width direction one end in the inner wall of long hole 423 are formed with downward and close to width side To the inclined surface 424 of the other end.

The quasi- fixed pin hole 321 for the insertion of quasi- fixed pin 41 is formed in support member 3a.The radial direction of quasi- fixed pin 41 Size than quasi- fixed pin hole 321 radial undersized.The intensity of quasi- fixed pin 41 is under the action of following load The intensity of fracture, the frictional force and earthquake which generates when moving along its length relative to lower layer side floor 1b The inertia force of truss 2 when generation is big, smaller than the buckling load of truss 2.

Long hole 322 is not formed in support member 3a.

Quasi- fixed pin 41 is as the quasi- fixed pin 41 of embodiment 1, and movement downwards is by the inclination of supporting plate 42 Face 421 constrains.In the case where extensive earthquake occurs, when compressive load acts on truss 2, in the buckling load of truss 2 It acts on before truss 2, quasi- fixed pin 41 is broken, and the part of the quasi- fixed pin 41 of fracture is along the inclined surface of supporting plate 42 421 It is moved in the width direction and falls.Remaining part is moved along its length together with support member 3a in quasi- fixed pin 41, When building shakes towards negative sense, the size L1 between the vertical piece 31 and supporting plate 42 of support member 3a becomes original size, Original position is returned to by self weight with the quasi- fixed pin 41 that support member 3a is moved together.Other structures and embodiment 1~3 is identical.

As described above, escalator according to embodiment 4 of the present invention, due to not having anchor pin 52, In the not formed long hole 322 for 52 insertion of anchor pin of support member 3a, it is thus possible to be formed as helping automatically than embodiment 1 The simpler construction of ladder.About other effects, effect same as embodiment 1 can be obtained.

Embodiment 5

Figure 18 is the side view for showing the upper layer side section of the escalator of embodiments of the present invention 5.Quasi- fixed mechanism Supporting plate 42 is included, upper layer side floor 1a is fixed in, is formed with pit 425 in upper surface；And friction portion 47, it sets In the lower surface of support member 3a, and it is inserted into pit 425.It is formed in friction portion 47 with upward and far from purlin The inclined surface 471 that the mode of frame 2 is inclined relative to horizontal.It is formed with inclined surface 471 in pit 425 equally relative to water The inclined inclined surface of plane.Slide unit 51 configuration in the upper surface of supporting plate 42 than be formed with pit 425 partially away from The region of truss 2.Other structures are identical as Embodiments 1 to 4.

Figure 19 is the figure for showing the balance of the power in friction portion 47 of Figure 18.According to the friction coefficient μ in friction portion 47 and friction The tiltangleθ of the inclined surface 471 in portion 47 with respect to the horizontal plane, determine the constraint of the movement of truss 2 is released from, truss 2 is to connecing The direction of nearly upper layer side floor 1a starts mobile power.Each the one of on-fixed side and the quality m of quasi- affixed side sub-truss 2 Partly, reduction, compressive load F act on truss 2 when the size between upper layer side floor 1a and lower layer side floor 1b is than installation In the case of, truss 2 along the condition that the inclined surface 471 in friction portion 47 floats is determined according to following formulas (1).Wherein, g table Show acceleration of gravity.

Fsinθ>μFcosθ+μmg/2×sinθ+mg/2×cosθ (1)

If arranging above-mentioned formula (1) for F, following formulas (2) are obtained.

F>mg/2×(μsinθ+cosθ)/(sinθ-μcosθ) (2)

Friction coefficient μ and tiltangleθ are designed to that the F for showing above-mentioned formula (2) becomes following load, the load ratio purlin The inertia force of truss 2 when the frictional force and earthquake that frame 2 generates when moving along its length relative to lower layer side floor 1b occur Greatly, the buckling load than truss 2 is small.

Figure 20 is the calculating knot of the relationship of the friction coefficient μ and tiltangleθ when showing the self weight mg for setting truss 2 as 100kN The table of fruit.It is found that when friction coefficient μ is smaller, tiltangleθ is bigger, the easier inclined surface 471 along friction portion 47 of truss 2 Float.In this embodiment, the buckling load of truss 2 is 300kN, truss 2 is moved relative to lower layer side floor 1b along its length When truss 2 when occurring of the frictional force that generates and earthquake inertia force be 80kN in the case where, if set friction coefficient μ as 0.3, set Tiltangleθ is 30, then the ruler when middle and small scale earthquake occurs, either between upper layer side floor 1a and lower layer side floor 1b The direction that the very little direction to broaden still narrows, friction portion 47 will not all be moved from pit 425.

Figure 21 is to show the friction portion 47 of Figure 19 departing from the side view of the state of pit 425.In the pressure for acting on truss 2 In the case that contracting load F is more than 212kN, truss 2 floats along inclined surface 471 and climbs on slide unit 51, thus makees Truss 2 is not acted on for the 300kN of buckling load, and the size between support member 3a and support member 3b corresponds to upper layer side building Layer 1a and lower layer side floor 1b between size variation and change.Then, when upper layer side floor 1a and lower layer side floor 1b it Between size when broadening, friction portion 47 is inserted into pit 425, is reverted to and state identical when installing.

As described above, escalator according to embodiment 5 of the present invention, with the embodiment constructed as follows 1~4 escalator is compared, and the limit that the length of quasi- fixed pin 41 generates the number that truss position is restored automatically can be eliminated System, the construction refer to: by the fracture of quasi- fixed pin 41, quasi- fixed mechanism releases the constraint to truss 2, quasi- fixed pin 41 Length generates limitation to the number that the position of truss 2 is restored automatically.

Embodiment 6

Figure 22 is the top view for showing the upper layer side section of the escalator of embodiments of the present invention 6, Figure 23 be along The XXIII-XXIII line of Figure 22 to pseudosection, Figure 24 be along Figure 22 XXIV-XXIV line to pseudosection.Standard is solid Determining mechanism has detection close to the force snesor 48 of power and the actuator 49 for shifting quasi- fixed pin 491, and actuator 49 wraps The quasi- fixed pin 491 as constraint piece is included, quasi- fixed pin 491 is in constraint support member 3a relative to upper layer side floor 1a along length The constrained of the movement in direction and the limit for releasing the movement to support member 3a relative to upper layer side floor 1a along its length It is shifted between the releasing position of system.The intensity of quasi- fixed pin 491 is not broken effect has the buckling load of truss 2 Intensity.

Actuator 49 has spring (not shown), which jacks up quasi- fixed pin 491 when usual, by quasi- fixed pin 491 position is set as constrained.In the case where the position of quasi- fixed pin 491 is constrained, quasi- fixed pin 491 is inserted into It is formed in the quasi- fixed pin hole 321 of support member 3a.Since quasi- fixed pin 491 is inserted into quasi- fixed pin hole 321, branch Support part part 3a is restrained relative to the movement of upper layer side floor 1a along its length, and truss 2 is relative to upper layer side floor 1a along length The movement for spending direction is restrained.

Actuator 49 resists the strength of spring and attracts quasi- fixed pin 491 downwards, thus makes quasi- fixed pin 491 from constraint Displacement to release position.In the case where the position of quasi- fixed pin 491 is to release position, quasi- fixed pin 491 is fixed from standard Pin is pulled out in hole 321.Since quasi- fixed pin 491 is pulled out from quasi- fixed pin in hole 321, to support member 3a relative to The constraint of the movement of upper layer side floor 1a along its length is released from, to truss 2 relative to upper layer side floor 1a along its length The constraint of movement be released from.

When usual and in the case where middle and small scale earthquake occurs, the position of quasi- fixed pin 491 is set as about by actuator 49 Beam position.In the case where middle and small scale earthquake occurs, although when size between upper layer side floor 1a and lower layer side floor 1b And increase when reducing, but support member 3a is not moved along its length relative to upper layer side floor 1a.As a result, truss 2 do not move along its length relative to upper layer side floor 1a.

On the other hand, in the case where extensive earthquake occurs, in on-fixed side, the vertical piece 33 of support member 3b is under Gap between layer side floor 1b disappears, and compressive load acts on truss 2, and force snesor 48 detects the load of specified value or more Lotus, actuator 49 are displaced to quasi- fixed pin 491 from constrained and release position according to the signal for carrying out force sensor 48.When When the position of quasi- fixed pin 491 becomes releasing position, in quasi- affixed side, support member 3a is also relative to upper layer side floor 1a along length Direction movement is spent, the gap between the vertical piece 31 and upper layer side floor 1a of support member 3a reduces.Correspond to upper layer side as a result, The variation of size between floor 1a and lower layer side floor 1b, support member 3a are moved along its length relative to upper layer side floor 1a It is dynamic, it disappears to the compressive load of truss 2.

When building starts to shake in the opposite direction, size restoration between upper layer side floor 1a and lower layer side floor 1b at Size originally, thus actuator 49 makes quasi- fixed pin 491 from displacement is released to constrained.As a result, helping automatically Ladder reverts to original state automatically.Other structures are identical as Embodiments 1 to 5.

As described above, escalator according to embodiment 6 of the present invention, it is in embodiment 1 to 4, quasi- Fixed mechanism is that the construction of the constraint to truss 2 is released by making the fracture of quasi- fixed pin 41, thus the length of quasi- fixed pin 41 Limitation is produced to the number that truss position is restored automatically, but since quasi- fixed pin 491 is not broken, it is thus possible to elimination pair Restore the limitation of number.

In addition, illustrating the structure of following actuator 49 in above embodiment 6: according to carrying out force sensor 48 Signal stretches out quasi- fixed pin 491 and retraction, thus constrains support member 3a relative to upper layer side floor 1a along its length It is mobile, or the constraint of the movement to support member 3a relative to upper layer side floor 1a along its length is released, but in addition to standard is fixed Other than the stretching of pin 491 and retraction, or such actuator structure: for example pass through clamp standoff component as brake disc 3a constrains the movement of support member 3a along its length relative to upper layer side floor 1a, by releasing the folder to support member 3a It holds to release the constraint of the movement to support member 3a relative to upper layer side floor 1a along its length.

In addition, as passenger conveyors, be illustrated by taking escalator as an example in each above embodiment, but It can be mobile pavement.

Label declaration

1a upper layer side floor；1b lower layer side floor；2 truss；2a length direction one end；2b length direction the other end； 3,3a, 3b support member；6 width direction fixtures；31 vertical pieces；32 lateral pieces；33 vertical pieces；34 lateral pieces；41 quasi- fixed pins； 42,43 supporting plate；44 cylinder barrels；45 springs；46 pressing plates；47 friction portions；48 force snesors；49 actuators；51 slide units；52 anchors Rationed marketing；321 quasi- fixed pin holes；322 long holes；323 quasi- fixed pin holes；411 notch；421 inclined surface；422 long holes；423 is long Hole；424 inclined surface；425 pits；461 inclined surface；471 inclined surface；491 quasi- fixed pins.

Claims (14)

1. a kind of passenger conveyors are supported on by a support member of the length direction one end setting in truss and are built A floor for building object is supported on institute by another support member being arranged in length direction the other end of the truss Another floor of building is stated, the passenger conveyors have quasi- fixed mechanism, which carries out to the truss To the constraint of the movement in the direction close to one floor or the releasing of the constraint, wherein

The passenger conveyors have truss resetting-mechanism, to the truss to described in the direction close to one floor Mobile constraint is released from, towards make the truss far from the direction of one floor leave power act on the truss and In the case where between one floor, it is moved along the length direction relative to another described floor in the truss Before, the truss resetting-mechanism moves the truss along the length direction relative to one floor, makes the truss Size between one floor becomes preset predetermined size.

2. passenger conveyors according to claim 1, wherein

It is acted between the truss and one floor towards the direction for making the truss close to one floor Close to power size be less than preset specified value in the case where, the quasi- fixed mechanism constrains the truss to close to described The movement in the direction of one floor, in the case where the size close to power is the specified value or more, the quasi- fixed machine Structure release to movement from the truss to the direction close to one floor constraint.

3. passenger conveyors according to claim 2, wherein

The specified value is than the friction that generates when the truss is moved relative to another described floor along the length direction Power or according to design basis assume maximum earthquake when the truss inertia force it is big, than the buckling load of the truss It is small.

4. passenger conveyors according to any one of claims 1 to 3, wherein

The quasi- fixed mechanism has a quasi- fixed pin, the quasi- fixed pin be inserted into be formed in one support member standard it is solid In rationed marketing hole, movement of the truss to the direction close to one floor is constrained,

The quasi- fixed mechanism is released to the truss by the fracture of the quasi- fixed pin to close to one floor The constraint of the movement in direction.

5. passenger conveyors according to claim 4, wherein

The quasi- fixed mechanism has supporting plate, which is fixed at than quasi- fixed pin hole position on the lower In one floor, and it is formed with the inclined surface being inclined relative to horizontal,

The lower end of the quasi- fixed pin and the inclination face contact, thus the quasi- fixed pin is supported on the supporting plate.

6. passenger conveyors according to claim 4, wherein

The quasi- fixed mechanism includes cylinder barrel, and the lower end of the quasi- fixed pin is inserted into the cylinder barrel；Spring is set to The cylinder barrel presses the quasi- fixed pin upwards；And pressing plate, one support member is fixed in, described in limitation The movement of quasi- fixed pin upwards.

7. passenger conveyors according to claim 3, wherein

The quasi- fixed mechanism includes supporting plate, is fixed in one floor, is formed with pit in upper surface；And Friction portion is set to one support member, and is inserted into the pit,

The friction portion be formed with upward and far from the length direction one end inclined surface.

8. passenger conveyors according to claim 7, wherein

The coefficient of friction for setting the friction portion as μ, set the inclination angle of the inclined surface with respect to the horizontal plane as θ, set the purlin In the case that the quality of frame is m, sets acceleration of gravity as g, the coefficient of friction and the inclination angle are determined so that following formula Value become the specified value,

mg/2×(μsinθ+cosθ)/(sinθ-μcosθ)。

9. passenger conveyors according to claim 1, wherein

The quasi- fixed mechanism includes force snesor, and detection direction makees the truss close to the direction of one floor For between the truss and one floor close to power；Actuator comprising constraint piece, and according to the force snesor Testing result shift the constraint piece, the constraint piece is constraining one support member relative to one Floor is along the constrained of the length direction moved and releasing to one support member relative to one floor It is shifted between the releasing position for the constraint of the length direction moved.

10. passenger conveyors according to claim 2 or 3, wherein

The quasi- fixed mechanism includes force snesor, detects described close to power；Actuator comprising constraint piece, and according to institute The testing result for stating force snesor shifts the constraint piece, and the constraint piece is opposite in the one support member of constraint It along the constrained of the length direction moved and is released to one support member relative to institute in one floor A floor is stated to be shifted between the releasing position for the constraint of the length direction moved.

11. passenger conveyors according to any one of claims 1 to 3, wherein

The truss resetting-mechanism has the slide unit being set between one floor and one support member,

The truss is released to the constraint of the movement in the direction close to one floor, the truss and one Size between floor is less than the predetermined size and the power of leaving acts between the truss and one floor In the case where, the slide unit makes to move relative to one floor along the length direction in one support member When the frictional force that generates be less than and moved relative to another described floor along the length direction in another described support member When the frictional force that generates.

12. passenger conveyors according to any one of claims 1 to 3, wherein

The truss resetting-mechanism has the friction member being set between another described floor and another described support member,

The truss is released to the constraint of the movement in the direction close to one floor, the truss and one Size between floor is less than the predetermined size and the power of leaving acts between the truss and one floor In the case where, the friction member makes in another described support member relative to another described floor along the length direction The frictional force generated when mobile is greater than to be moved relative to one floor along the length direction in one support member When the frictional force that generates.

13. passenger conveyors according to any one of claims 1 to 3, wherein

The truss resetting-mechanism has anchor pin, which is fixed in one floor, and is inserted into along described Length direction is formed extended at both sides in the long hole of one support member,

The power of leaving act between the truss and one floor and the truss and one floor it Between size be the predetermined size in the case where, farthest away from the portion of the truss in the inner wall of the anchor pin and the long hole Tap touching, it is mobile to the direction far from one floor thus to limit the truss.

14. a kind of fixing means of passenger conveyors, which passes through the length direction one end setting in truss One support member is supported on a floor of building, another by being arranged in length direction the other end of the truss One support member is supported on another floor of the building, and the passenger conveyors have quasi- fixed mechanism, the standard Fixed mechanism carry out to movement from the truss to the direction close to one floor constraint or the constraint releasing,

The fixing means of the passenger conveyors is with the following process:

Release to the movement from the truss to the direction close to one floor constraint；And

After releasing to the process of the constraint of the movement, towards make the truss far from the direction of one floor from In the case that opening force acts between the truss and one floor, in the truss relative to another described floor edge Before the length direction is mobile, moves the truss along the length direction relative to one floor, make the purlin Size between frame and one floor becomes preset predetermined size.